Bibcode
Giammanco, C.; Beckman, J. E.; Cedrés, B.
Bibliographical reference
Astronomy and Astrophysics, Volume 438, Issue 2, August I 2005, pp.599-610
Advertised on:
8
2005
Journal
Citations
30
Refereed citations
26
Description
In this article we first outline the mounting evidence that a
significant fraction of the ionizing photons emitted by OB stars within
H ii regions escape from their immediate surroundings, i.e from what is
normally defined as the H ii region, and explain how an H ii region
structure containing high density contrast inhomogeneities facilitates
this escape. Next we describe sets of models containing inhomogeneities
which are used to predict tracks in the commonly used diagnostic
diagrams (based on ratios of emission lines) whose only independent
variable is the photon escape fraction, ξ. We show that the tracks
produced by the models in two of the most cited of these diagrams
conform well to the distribution of observed data points, with the
models containing optically thick inhomogeneities (“CLUMPY”
models) yielding somewhat better agreement than those with optically
thin inhomogeneities (“FF” models). We show how variations
in the ionization parameter U, derived from emission line ratios, could
be due to photon escape, such that for a given region from which 50% of
its ionizing photons leak out we would derive the same value of U as for
a region with no photon escape but with an input ionizing flux almost an
order of magnitude higher. This effect will occur whether the individual
inhomogeneities are optically thick or thin. Photon escape will also
lead to a change in the derived value of the radiation hardness
parameter, and this change differs significantly between models with
optically thin and optically thick clumps. Using a rather wide range of
assumptions about the filling factor of dense clumps we find, for a
selected set of regions observed in M 51 by Díaz et al. (1991) an
extreme limiting range of computed photon escape fractions between near
zero and 90%, but with the most plausible values ranging between 30% and
50%. We show, using oxygen as the test element, that models with
different assumptions about the gas inhomogeneity will tend to give
variations in the abundance values derived from diagnostic diagrams, but
do not claim here to have a fully developed set of diagnostic tools to
improve abundance determinations made in this way. We do present an
important step towards an eventual improvement in abundance
determinations: the combination of line ratios with the absolute
Hα luminosity of a given H ii region, which allows us to determine
the photon escape fraction, and hence resolve the degeneracy between U
and ξ. We use observational data of this type show that a large set
of H ii regions in M 101 observed by Cedrés & Cepa (2002) all
show significant photon escape with values of ξ ranging up to 60% in
the “leakiest” cases.